MabSelect VH3 Protein A affinity resin effectively separates antibody species containing different numbers of VH3 domain and shows improved aggregate separation capability.

MabSelect VH3 is a new Protein A resin recently launched by Cytiva. According to the manufacturer, the Protein A ligand of MabSelect VH3 has been engineered to disrupt and reinforce its Fc and VH3 binding capabilities, respectively. Thus, different from regular Protein A resins, this new Protein A resin has affinity for VH3 domain only.

CH1-specific affinity resins possess the potential of separating heterodimer from homodimers in asymmetric bispecific antibody purification.

CaptureSelect CH1-XL and Praesto 70 CH1 are two affinity media that specifically bind to the CH1 domain of an antibody. In the current work, we first demonstrated that these two CH1-specific affinity media bound to different monoclonal antibodies (mAbs) with varied strengths under identical conditions. We previously had observed the same on a Protein L-conjugated resin and showed that such a property could facilitate homodimer removal in asymmetric bispecific antibody (bsAb) purification.

Monitoring of the disulfide scrambled species by mixed-mode SEC-HPLC during the purification of a bispecific antibody.

Size-exclusion chromatography-high performance liquid chromatography (SEC-HPLC) is an analytical method routinely used for assessing aggregation content in protein samples. As SEC-HPLC separates analytes based on their hydrodynamic radius, it generally lacks the capability of differentiating species that are similar in size. Recently while purifying a bispecific antibody (bsAb), we noticed that SEC-HPLC can provide certain degree of resolution between the target bsAb and a disulfide scrambled form, although these two species were identical in molecular weight.

CaptureSelect FcXP affinity medium exhibits strong aggregate separation capability.

Protein A affinity chromatography has been widely used for initial product capture in recombinant antibody/Fc-fusion purification. However, in general Protein A lacks the capability of separating aggregates (unless the aggregates are too large to enter the pores of resin beads or have their Protein A binding sites buried, in which case the aggregates do not bind). In the current work, we demonstrated that CaptureSelect FcXP affinity medium exhibited strong aggregate separation capability and effectively removed aggregates under pH or conductivity gradient elution in two bispecific antibody (bsAb) cases.

Unravelling the reason for different binding behaviors exhibited by antibody aggregates towards preparative and analytical Protein A columns.

We previously showed that the root cause of low Protein A step yield observed for certain antibodies/Fc-fusions is the presence of non-binding aggregates in cell culture harvest. A pre-assumption for the above conclusion is that the aggregates, while do not bind to the preparative Protein A column, can bind to the analytical Protein A-high performance liquid chromatography (HPLC) column used for titer measurement. In the current work, using materials from a previous case with the low yield issue, we confirmed that non-binding aggregates in preparative Protein A flow-through can indeed bind to the analytical Protein A column.

SEC-HPLC analysis of column load and flow-through provides critical understanding of low Protein A step yield.

For a certain number of mAbs, bispecific antibodies (bsAbs) and Fc-fusion proteins that we worked on, the Protein A capture step experienced low yield (i.e., ∼80%).

Acidic pH or salt treatment can convert soluble antibody aggregates in culture harvest into monomers and improve Protein A chromatography step yield.

While purifying a regular monospecific antibody, we found that the Protein A step yield was much lower than expected. Further studies revealed that the antibody formed large-size aggregates that did not bind to the Protein A resin, hence leading to dropped recovery. In an attempt to solve this low yield issue, we found that mildly acidic pH or ammonium sulfate treatment can partially convert the aggregates into monomers.

Complementary methods for monitoring hole-hole homodimer associated with a WuXiBody-based asymmetric bispecific antibody.

WuXiBody is a bispecific antibody (bsAb) platform developed by WuXi Biologics. Its key feature is the replacement of one parental antibody's CH1/CL region with the T-cell receptor (TCR) constant domain, which prevents mispairing between non-cognate heavy chain and light chain. In addition, heavy chain heterodimerization in asymmetric WuXiBody molecule is promoted by the knobs-into-holes (KiH) technology.

Antibody aggregation can lead to reduced Protein A binding capacity and low step yield.

Protein A affinity chromatography has been widely used for antibody capture and initial purification. In general, the yield of this step is relatively high (i.e.

Protein A and CaptureSelect FcXP Affinity Resins Possess the Capability of Differentiating Hole-hole Homodimer Isoforms.

Background: Knobs-into-holes (KiH) technology has been widely used in asymmetric bispecific antibody (bsAb) construction to promote heavy chain heterodimerization. However, despite the great improvement of heterodimer formation by this strategy, homodimers (especially the holehole homodimer) can still be generated at low levels. Consequently, hole-hole homodimer is a common byproduct associated with the production of KiH bsAbs.

SAC-TRAIL, a novel anticancer fusion protein: expression, purification, and functional characterization.

Recombinant protein pharmaceutical agents have been widely used for cancer treatment. Although tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) has broad-spectrum antitumor activity, its clinical applications are limited because most tumor cells eventually develop resistance to TRAIL-induced apoptosis through various pathways. Prostate apoptosis response-4 (Par-4) selectively induces apoptosis in cancer cells after binding to the cell surface receptor, GRP78.

Cadmium sulfide net framework nanoparticles for photo-catalyzed cell redox.

A strategy for synthesizing cadmium sulfide net framework (CdS-NF) nanoparticles was developed in a water-based system under mild reaction conditions. The CdS-NFs have not only the excellent photocatalytic properties of CdS, but also the large surface area and diverse porous structures of a metal-organic framework. An -CdS-NF hybrid system was constructed using NADH regeneration to promote the conversion of trimethylpyruvate acid to l--leucine.